Design, commissioning and performance of a device to vary the turbulence in a recirculating flume
Design, commissioning and performance of a device to vary the turbulence in a recirculating flume
Ambient turbulent flow structures are one of the key drivers that will determine the rate of wake recovery downstream of tidal turbines. For second and third generation arrays or farms such a parameter is critical for the determination of inter-device spacing and the optimisation of energy extraction per unit surface area. At present offshore flow characterisation is dominated by seabed or surface-mounted diverging-beam acoustic Doppler profilers that whilst having a good spatial capture cannot characterise turbulent flow structures to the same accuracy as single point converging laboratory-scale velocimeters. So a paradox presently exists: We can measure the (mean) flow characteristics at real tidal energy sites but lack the ability to accuracy ascertain high-frequency flow characteristic at discrete spatial locations. This is possible at laboratory-scale with convergent-beam devices but as we do not know the real site conditions replication at small-scale can only be approximated. To date there has been few laboratory studies where the ambient flow turbulence has been varied. The standard method is to generate turbulence from a static structure such as a grid. Here we have developed an articulated rig that has the ability to oscillate cylindrical members along two axes in the flow upstream of tidal turbine models. Initial results presented in this paper show the effect upon the ambient flow that the turbulence-generating rig can impose and the effects upon wake dissipation for varying levels of turbulent length and time scales. Also the formation and insistence of turbulent structures shed from the device are reported. As expected increasing ambient turbulence intensity serves to dissipate the turbine wake more rapidly and whilst we cannot directly relate these laboratory flow characteristics to full-scale tidal energy sites at present it is hoped that offshore measurement technology and that of laboratory replication can converge so that device performance prediction can be performed at smaller-scale and at a corresponding lower cost to the technology.
Myers, L.E.
b0462700-3740-4f03-a336-dc5dd1969228
Shah, K.D
ccd09636-971e-4f96-acf8-aa80a06d1eca
Galloway, P.W.
958479f9-d4dc-426c-aadb-82b37103c5ea
2 September 2013
Myers, L.E.
b0462700-3740-4f03-a336-dc5dd1969228
Shah, K.D
ccd09636-971e-4f96-acf8-aa80a06d1eca
Galloway, P.W.
958479f9-d4dc-426c-aadb-82b37103c5ea
Myers, L.E., Shah, K.D and Galloway, P.W.
(2013)
Design, commissioning and performance of a device to vary the turbulence in a recirculating flume.
10th European Wave and Tidal Energy Conference, Aalborg, Denmark.
02 - 05 Sep 2013.
Record type:
Conference or Workshop Item
(Paper)
Abstract
Ambient turbulent flow structures are one of the key drivers that will determine the rate of wake recovery downstream of tidal turbines. For second and third generation arrays or farms such a parameter is critical for the determination of inter-device spacing and the optimisation of energy extraction per unit surface area. At present offshore flow characterisation is dominated by seabed or surface-mounted diverging-beam acoustic Doppler profilers that whilst having a good spatial capture cannot characterise turbulent flow structures to the same accuracy as single point converging laboratory-scale velocimeters. So a paradox presently exists: We can measure the (mean) flow characteristics at real tidal energy sites but lack the ability to accuracy ascertain high-frequency flow characteristic at discrete spatial locations. This is possible at laboratory-scale with convergent-beam devices but as we do not know the real site conditions replication at small-scale can only be approximated. To date there has been few laboratory studies where the ambient flow turbulence has been varied. The standard method is to generate turbulence from a static structure such as a grid. Here we have developed an articulated rig that has the ability to oscillate cylindrical members along two axes in the flow upstream of tidal turbine models. Initial results presented in this paper show the effect upon the ambient flow that the turbulence-generating rig can impose and the effects upon wake dissipation for varying levels of turbulent length and time scales. Also the formation and insistence of turbulent structures shed from the device are reported. As expected increasing ambient turbulence intensity serves to dissipate the turbine wake more rapidly and whilst we cannot directly relate these laboratory flow characteristics to full-scale tidal energy sites at present it is hoped that offshore measurement technology and that of laboratory replication can converge so that device performance prediction can be performed at smaller-scale and at a corresponding lower cost to the technology.
Text
EWTEC2013 - Myers et al preprint version.pdf
- Author's Original
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Published date: 2 September 2013
Venue - Dates:
10th European Wave and Tidal Energy Conference, Aalborg, Denmark, 2013-09-02 - 2013-09-05
Organisations:
Energy & Climate Change Group
Identifiers
Local EPrints ID: 356974
URI: http://eprints.soton.ac.uk/id/eprint/356974
PURE UUID: 5d017cbd-6710-4032-9ee9-32455b9d8007
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Date deposited: 15 Oct 2013 12:40
Last modified: 15 Mar 2024 03:12
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Contributors
Author:
K.D Shah
Author:
P.W. Galloway
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